Camera magazine



9 Sheets-Sheet 1 l. W. DOYLE ETAL CAMERA MAGAZINE Filed Nov. 13. 1943 July 9, 1946.

July 9, 1946. l. w. DoYLE ETAL 2,403,587

CAMERA MAGAZINE Filed Nov. 13, 1943 9 Sheets-Sheet 2 m@ S v w mum July 9, 41946. l. w.. DoYLE ETAL CAMERA MAGAZINE Filed NOV. 15, 1945 9 Sheets-Sheet 3 INVENTORS Irvin Wo Ze BY Reyinal' e //.Zf "MQ ATTOR sys.

- July 9, 1946. y l. w. DOYLE ErL 2,403,587

CAMERA MAGAZINE Fiied Nov. 15, 1943 9 Sheets-Sheet 4 3 wmv /49 July 9 1946- I 1. Aw. DOYLE ET AL 2,403,587

CAMERA MAGAZ INE Filed Nov. 15, 1945 9 Sheets-Sheet 6 July 9, 1946. l. w. DoYLE ETAL CAMERA MAGAZINE Filed Nov. l5, 1943 9 Sheets-Sheet 7 INVENTORS [rz/ng W July 9, 1946. l. w. DoYLE ETAL 2,403,587

CAMERA MAGAZINE Filed Nov. 15, 1943 9 Sheets-Sheet 8 July 9, 1946. l. w. DoYLE ETAL CAMERA MAGAZINE Filed Nov. 13, 1945 9 Sheets-Sheet 9 I IN VEN T ORS huh l Z151@ EEEZEEEEEIQ@ @@ZQQQQ@ ZZQQEQ l2@ @ZEE -ZZ Z EZE @EQ2 E @@ZZWJZ ZZEZ EEEZZ @@@QZZZQZ QQEZZZZQZ @ZZZZZZZW @@ZZEZZZEZZ@ Patented July 9, 1946 CAMERA MAGAZINE Irving W. Doyle, Massapequa, and Reginald A. White, Pleasantville, N. Y., assignors to Fair child Camera and Instrument Corporation, a

corporation of Delaware Application November 13, 1943, Serial No. 510,146

Claims. 1

This invention relates to cameras, and more particularly to a magazine adapted to be detachably secured to an aerial camera.

Aerial camera magazines of the character here under consideration are designed to carry strip film which, in the case of a large camera capable of taking pictures 9 X 18, for eXample, has considerable weight. Cameras of this type are used for mapping and reconnaissance work, and most of the cameras in present use are war-time adaptations of conventional aerial mapping cameras. The exigencias of war-time applications of these cameras, however, demonstrated that the film capacity thereof was insufficient, one reason for which being that it is often necessary to mount the camera in an inaccessible position in the aircraft, thus making it difficult if not impossible to effect magazine interchange to renew the film supply during a mission.

It further became evident that available forms of magazines could not be overloaded thus to increase the film carrying capacity and still operate efficiently, by reason of diiculties arising through the substantially increased factors of inertia and momentum of the loaded iilm supply and take-up spools. Additional difficulties were encountered in accurately metering the film where an extremely large quantity thereof was loaded in they magazine because of the Very substantial variation in the diameter of the roll of film on the spools during the taking of a large number of successive photographs.

Still further diiculties were encountereda in properly supporting the heavily loaded supply and take-up spools, particularly during evasive action of the aircraft, during which the aircraft and accordingly the camera is subjected to violent stresses by reason of the evolutions of the aircraft.

It is accordingly among the objects of this invention to provide a large capacity magazine for an aerial camera which is extremely sturdy and durable in construction, eflicient and dependable in operation, and capable of obviating the abovementioned difficulties in addition to others in a practical and emcient manner.

The invention accordingly consists in the features of construction, combinations of elements, and arrangements of parts as will be exemplified in the structure to be hereinafter described, and the scope of the application of which will be indicated in the following claims.

In the drawings, wherein we have shown one form of our invention,

Figure 1 is a top plan View of the magazine 2 with the cover thereof removed to illustrate various internal mechanisms;

Figure 2 is a sectional elevation taken along the line 2 2 of Figure 1;

Figure 3 is a fragmentary horizontal section taken along the line 3 3 of Figure 2;

Figure 4 is an enlarged fragmentary vertical section showing in greater detail the mechanism shown in the right-hand portion of Figure 2;

Figure 5 is an enlarged 4fragmentary vertical section showing in greater detail the mechanisms in the left-hand portion of Figure 2;

Figure 5A is a fragmentary section taken along the line 5A 5A of Figure 5;

Figure 6 is a fragmentary horizontal staggered section taken along the line 6 6 of Figure 5;

Figure '7 is an enlarged fragmentary horizontal section taken along the line 1 1 of Figure 4;

Figure 8 is a perspective view of a planetarylike gear system comprising a part of the film ytake-up spool clutch;

Figure 9 is a vertical section taken along the line 9 9 of Figure 4;

Figure 10 is a fragmentary vertical section taken along the line l-IU of Figure 4;

Figure 11 is a fragmentary vertical section taken along the line Il H of Figure 5;

Figure 12 is a fragmentary vertical section taken along the line |2 |2 of Figure 5;

Figure 13 is an enlarged fragmentary elevation of a portion of the film supply and take-up spool support as viewed along the line |3 |3 in Figure 1;

Figure 14 is a top plan view of the camera vacuum back against which the film is held flat at the focal plane during an exposure, portions of this view being broken away to illustrate various structural details of this element;

Figure 15 is a staggered section taken along the line |5 |5 of Figure 14; and

Figure 16 is a side elevation of an aerial camera including our lm magazine.

Similar reference characters refer to similar parts throughout the various views of the drawings.

In Figure 16, we have shown an aerial camera which consists of a cone-shaped body Zil in which the lens and shutter is disposed, a body 2l in which is contained the camera driving motor and the main camera winding mechanism, and our roll film magazine generally indicated at 22 which is adapted to be detachably mounted on the body. The camera is adapted to be mounted on aircraft often in a position wherein it is inaccessible during night, and accordingly the camera is fully automatic and remotely controllable by the :proper individual of the aircraft personnel. The following description, however, is directed solely to magazine 22.

As shown in Figure 2, magazine 22 includes a base casting 23 having four upwardly extending sides 24, 25, 26 (Figure l) and 21, the upper edges of which are provided with a continuous groove or slot 28 in which is received the edge of a cover 29 which is detachably secured on the magazine to cover the operating mechanisms therewithin. Thus base 23, the walls extending therefrom, and cover 29, form an enclosure in which are disposed a film supply spool 30, a film take-up spool 3| and various operating mechai nisms therefor which will be described in detail below.

Disposed within the above-described enclosure is an upstanding bracket or support 32 (Figure l) which is fastened to base 23 by suitable screws 33 and which, as shown in Figure 2, forms a partition which lies between the film spools and 3| and the operating mechanism therefor. Secured to partition 32 in any suitable manner is a casting 34 (Figure 10i) which, with the partition, comprises a unitary sub-assembly generally indicated at 35, constituting practically the entire operating mechanism. Thus it may be seen that this sub-assembly 35 is fastened to the base 32 of the magazine by screws 33 so as readily to be installable or removable with respect thereto as a unit. At that side of the base casting 32 opposite from the assembly 35 is an upright casting 36 (Figure 1) which is fastened to the base casting 32 in any suitable y:

manner. Casting 36 is tied to partition 32 by a tie plate 31 fastened at its opposite ends to the partition and casting by suitable screws. Thus the assembly is sufficiently rigid to withstand the substantial stresses to which the camera Film spool mounts (Figures 1 and 13) Y As shown in Figure 10, partition 32 also has mounted therein a small ball bearing 42 which f is coaxial with a similar bearing 43 mounted in casting 34 and these two bearings rotatably mount a spindle 44 to the inner end of which is fastened a pivot 45 adapted to receive one end of the film take-up spool 3|. The other end of the take-up spool 3| is mounted on a pivot 45 (Figure 1), which is movable toward and away from the take-up spool in the same manner as supply spool pivot 4|. Thus pivots 4| and 46 are respectively mounted on arms 41 and 48 which are hinged to casting 36 by means of pins 49 and 56. This hinged connection permits the arms 41 and 48 to be swung toward and way from their respective film spools to permit insertion and removal of the spools from the magazine.,`

As is better shown in Figure 13, springs 5| and 52 are respectively associated with pins `49 and 50 and bear respectively against arms 41 and 48 to bias these arms into their spool engaging po.

sition, as shown in solid lines in Figure 1. Pref- `tion after the film spools are in place.

erably we provide a bar 53, pivoted as at 54 t0 upright casting 36 and adapted to be swung to the position shown so that its ends lie in back of arms 41 and 48, thus to prevent swinging of the arms against the bias of their' springs from their spool engaging position. Hence the spools are prevented from becoming dislodged accidentally during operation of the camera. When it is desired to remove the spools from the magazine, bar 53 may be rotated 90, whereupon arms 41 and 43 may be pivoted about their respective pins, thus permitting removal of the film supply and take-up spools. Preferably there is a spring (not shown) associated with bar 53 and its pivot, which biases the bar t0 its horizontal position shown in Figure 13, so as to preclude any possibility of the bar remaining in its unlocked posi- Although springs 5| and 52 press arms 41 and 48 together vwith their spool pivots 4| and 46 into spool engaging position, these springs are not sufficiently strong to support the full weight of the loaded spools in the event that the magazine should become tilted during operation. Thus it will appear that bar 53 locks the spool pivot supporting arms in proper operative position, assuring maintenance of the film spools in their proper positions during operation of the camera.

Film feeding mechanism (Figures 2, 4 9, 10, 11)

Fastened to magazine base 23 (Figure l0) is a focal plane casting, generally indicated at 55, which is secured to the magazine base in any suitable manner over an aperture 23a in the base. The edges of base 23 on opposite sides of aperture 23a are slightly recessed to form opposed grooves, such as groove 23h, between the focal plane casting 55 and base 23 for the passage of film. Thus when the film is loaded in the magazine, the leading end thereof is drawn from the film supply spool 3D (Figure 2), is passed over a guide roller 51 (Figures 2 and 5) between focal plane casting 55 (Figure 10) and base casting 23, around a drive roller 58, beneath a pressure roller 59 (Figure 4) over a tension roller 60 and thence onto the take-up spool 3| where it may be secured in any suitable manner as, for example, by a piece of tape. Thus, as will now be described, the iilm is drawn from the supply spool in accurate amounts through the operation of the mechanism in assembly 35 (Figure 10) which drives the feed roller 58 (Figure 7) and also the take-up spool 3| (Figure 10).

The entire film magazine mechanism is operated from the camera winding mechanism in body 2| (Figure 16) by means of a slotted coupling 5| (Figures-2 and l1), the bottom surface of which is iiush with the bottom of base 23. Coupling 6| (Figure 11) is fastened to the lower end of a shaft 82 journaled by a ball bearing 63 mounted in the lower portion 34a of casting 34. To the upper end of shaft 62 is attached a bevel gear 64 which meshes with a bevel gear 65 secured on one end of a stud shaft 66 journaled at its opposite ends in ball bearings 61 and 68 mounted respectively in casting 34 and bracket 32. Bevel gear 55 includes a hub portion 65a on which is fastened a large spur gear 69 (see Figure 2) which meshes with a gear 10 which, as shown in Figure l0, is secured to a hub 1| pinned to a shaft 12, the opposite ends of which are mounted in ball bearixgs secured respectively in casting 34 and bracket 3 Also pinned to shaft 12 is an arm 13 (Figure 4) which carries a stud 14 on which is mounted a ,gear sector 75. VGear sector l5 (Figure 10) includes an arm I8 to which is fastened a stud 'li KVrotatably carrying a roller or cam follower i8. Follower 18 extends into a groove '19 formed in a xed cam 89 which may be fastened in any suitable manner to casting 34. Thus, as shaft V'l2 rotates, arm 'I3 and accordingly gear sector 'l5 rotate with it to drive the roller or follower 18 around in the cam groove T9.

Loosely mounted on shaft 12 is an assembly comprising a gear 8| and a gear 82 which, shown in Figure 10, are fastened to a hub 83 and accordingly rotate together. Gear sector (Figure 4,) meshes with gear 8l, while gear 82 meshes with a large gear 84 which in turn meshes with a smaller gear 85 fastened to the spindle 89 on one end of which the film feed drive roller 59 is carried. It will now appear that upon opera-- tion ofthe mechanism in body 2| (Figure 1) dSC 6| and accordingly shaft 52 and bevels 94 and 85 (Figure 1l) are driven, causing rotation of gears 89 and 18. Thus gear 18, in turn, drives shaft i2, and as the shaft rotates, arm 'i3 carries gear sector 'E5 and cam follower 78 with it. This gear train is so proportioned that the arm "I3 makes one rotation per cycle. As this arm rotates, gear 82 is given a motion consisting of the resultant of the motion of arm 13 about shaft i2 and the motion of sector 'l5 with respect to arm T3.

The position of these parts, as shown in Figure 4, corresponds to their position at the beginning or at the end of the cycle. In this position, as arm 73 rotates counterclockwise, roller I8 is forced toward the center of shaft 'l2 by groove 19 so that the motion of gear sector 'l5 with respect to arm if;

13 exactly cancels the motion of the arm. Therefore, gear 82 remains stationary during this initial movement. When arm 'i3 has rotated sufficiently for roller 'I8 to reach, for example, the position 18a, the path of the roller is changed so that the motion imparted to gear 82 by means of gear sector 75 operating through gear 8| will be added to the motion imparted to gear 82 due to the rotation of arm 13. If gear sector were restrained from moving with respect to arm i8, the sector teeth would impart a motion to gear 82 exactly the same as the motion of arm '13. In other words, if roller 78 does not move closer to or farther from the center of shaft 12, the entire arm assembly will move as a unit, carrying gear 82 with it. If roller 78 is permitted to move closer to the center of shaft 12, it decreases the motion imparted to gear 82. If roller 'i8 moves away from the center of shaft 12, as arm 'I3 rotates the motion imparted to gear 82 is increased. Thus, as noted above, during the first few degrees of motion at the beginning of the cycle, roller 1S moves closer to the center of shaft 12 and at such a rate, by reason of the contour of groove 19, that gear 82 is not moved at all. Following this initial movement, the motion of the roller transversely of shaft '12 is controlled so as to accelerate gear 82 gradually until roller 18 reaches a position indicated approximately at 18D. From this position until the roller reaches the position indicated at 18o, the roller is forced outward from the centerof shaft 12 at a constant velocity, and the relative motion of gear sector l5, with respect to arm 13, added to the motion of the arm itself, imparts a constant velocity to gear 82. From the position `l8c to the position '18d of the roller, the roller is controlled in such a way as to effect the gradual deceleration of gear 82. From position 18d to its solid line position, roller T8 is moved closer and closer to the center of shaft '12, and at a constant rate 6 designed to cancel exactly the rotated motions and leave gear 82atlrest. The solid line position of .roller 'IS represents the end of the cycle, as vwell as the beginning thereof.

Thus it will be seen that gear 82 throughout its operative cycleuof one revolution is first slowly accelerated from 'a rest position, then driven at a constant velocity, and then decelerated until its motion ceases. A similar motion is accordingly imparted to gear 84, and by this gear to the lm feed roller 58 through gear 85. It might be noted that the feed roller 58, as well as pressure roller 59, are both covered with rubber or similar material in order to increase the coefficient of friction thereof and thus hold the film slippage to a minimum to assure high accuracy of film metering during the cycle.

During the entire operative cycle of the magazine in which arm 13 makes one complete co-unterclockwise revolution coming to rest at the same position it occupied at the beginning of the cycle, it is obvious that gear 82 will also be given one complete turn counterclockwise. The motion of gear 82, however, does not start at the beginning of the cycle, and furthermore its motion is finished before the end of the cycle. Thegear ratio between gears 82, 84, and 85 is calculated to rotate the feed roller 58 sufficiently that its periphery will move the required amount of film during the cycleand yaccordingly draw the appropriate amount from the supply spool 38 (Figure 2) through the magazine. This film must, of course, be wound on the take-up spool 3|, and we have provided a mechanism to accomplish this which will now be described.

Film take-up mechanism As shown in Figure 10, sub-assembly includes a'drum 81 loosely mounted on shaft 44, which as pointed out above carries pivot at its inner end. The pivot supports the lm takeup spool 3|. Wrapped partially around drum 81 is a thin metallic strip or brake band 88 (Figure 4) one end of which is fastened as at 89 to casting 34. The other end of this brake band is secured to a rigid channel-shaped bar 90, the lower end of which is attached to a post 9| fixed to an arm 92, which arm is pivotally mounted on spindle 86 (Figures 2 and 9). Arm 92 (Figure 7) has its counterpart in an arm 94 at the opposite end of roller 60, and the free ends of these pivoted arms rotatably support the film tension roller 59 which, as shown in Figure 2, underlies the lm stri-p F, as the lm is wound on take-up spool 3i. Suitable spring means (not shown) are provided for biasing the arms 92 and 94, and accordingly the tension roller 68, clockwise, as viewed in Figure 2, thus to tension the lm between the feed roller 58 and the take-up spool 3 I.

The upper end of the brake band bar is slidably disposed between a pair of xed pins andSS, and as arm 92 pivots counterclockwise under the tension of the film, pin 9| moves toward the take-up spool 3|, thus permitting bar 90 to move to the left, which loosens the engagement between strip 88 and drum 81. The loosening of the engagement between strip 88 and drum 87 occurs when the slack in the film strip F has been substantially taken up. When there is too much slack in the film strip, then the spring bias on arms 92 and 94 pivots these arms clockwise, as viewed in Figure 2, which moves pin 9| away from the take-up spool 3| and accordingly tightens strip 88 about drum 81. As will be pointed out below, the loosening of the 7 strip on the drum stops the feeding movement of the drum, whereas the tightening of the strip 88 on drum 81 causes the nlm take-up spool to be driven and hence to wind film thereon.

Referring to Figure 10, spindle 44 has pinned thereto a. gear 91, the hub of which rotatably supports a gear 98 which meshes with gear 82 (see also Figure 4). Attached to gear 98 (Figures 8 and 10) are two studs 99 and |00, which rotatably carry meshing gears |0| and |02, respectively. Gear |0| also meshes with gear 91 while gear |02 meshes with a gear |03 which, as shown in Figure 10, is loosely mounted on spindle 44 and is attached to drum 81. Accordingly, it may be seen that as long as the brake band 88 is tight enough to hold drum 81 stationary, gear |03 is also held stationary. Since gear 02 (Figure 4) is rotated counterclockwise during the winding portion of the operative cycle, gear 98 is rotated clockwise. Hence, since gear |03 (Figure 4) is held stationary by drum 81, clockwise rotation virili be given to gear |02 as its center is carried around the center of shaft 44 by reason of the rotation of gear 98. This causes gear |0| to rotate counterclockwise about its center, thus to impart clockwise rotation to gear 91 which, as noted above, is pinned to shaft 44 (Figure 10). Thus shaft 44 is caused to rotate and spool pivot 4K5 accordingly rotates the take-up spool 3|, thus winding up the slack lm onto the spool.

When the lm slack has been entirely taken up, further rotation of the take-up spool 3| results in a tension in the film which presses the tension roller G0 (Figure 2) downwardly, causing the engagement between brake band 88 and drum 81 to slacken, as described above, thus permitting the drum 81 to rotate, rather than remain stationary, Of course, if the gear which rotates shaft 44 is not driven, the take-up spool remains stationary. The amount of the spring bias on arms 92 and 94 (Figure 7) tends to prevent any more film from being wound on spool 3|, and the spool either then slows down or stops. As it slows down, shaft 44 (Figure l0) likewise slows down, as well as gear |03. If gear 91 slows down sufficiently or stops, gear |0| will have to rotate clockwise (Figure 8) as its center, which is mounted on gear 98, is moved clockwise about the center of shaft 44 (Figure 4) due to the driving force provided by gear 82 which, of course, cannot be stopped during the operative cycle. This clockwise motion of gear |0| (Figure 8) results in counterclockwise rotation of gear |02 which, in turn, results in clockwise rotation of gear |03 and accordingly drum 81 (Figure l0). However, since the brake band 88 is loose, the drum will revolve with no appreciable effort. Actually during the winding cycle, brake band 88 is neither tight nor completely loose. Hence drum 81 and gear |03 are permitted to slip somewhat so that shaft 44 is turned just enough to keep the slack out of the film by taking up this slack on spool 3| as fast as the film feed roller 58 (Figure 4) feeds iilm through the magazine. Also, the arms 92 and 94 (Figure 4) are held substantially in a position of equilibrium or balance in which the brake band 88 (Figure 4) is neither tight nor completely loose, as noted above. film is balanced by the force of the spring bias on arms 92 and 94. Inasmuch as this spring bias is relatively light, it results in a greater slipping of the clutch comprising brake band 88 and drum 81. so that the torque input to gear 98 is rela- Thus the tension in the tively light since it need be merely sufficient to maintain the above-mentioned tension in the film. Thus it will appear that the torque input to the iilm take-up spool driving mechanism is a function of the tension of the film between the film feed roller 58 and the take-up spool 3|. It accordingly follows that the film take-up mechanism described comprises, in effect, a slipping clutch in which the transmitted torque may be controlled from anextremely low value to an extremely high value as load conditions change, by means of the slack in the film itself.

As noted hereinabove, trouble has been encountered in previous magazines of the character under consideration, particularly large magazines, whenever a large mass of lm was used and/or whenever the film had to be wound in an extremely short period of time. It is apparent that the gear ratio to the take-up spool 3| must be sufiiciently high to Wind the entire length of film required during the permitted portion of the operative cycle with the take-up spool empty. This portion of the cycle may be somewhere around 300 of the input winding shaft. Near the end of the mission when a large diameter of lm has been wound on the take-up spool, the entire length of film may be taken up in as little as 95, where a spool of the large capacity contemplated herein is used. Since the speed of the input shaft remains constant, the film winding speed under these conditions is extremely high, which means simply that a greater load is applied to the mechanism at the instant the iilm is started. This also means that when the required length of film has been wound there is substantial momentum generated which must be absorbed in order to stop the lm feed and takeup spools at the right time. Thus it follows that where the film is fed by means of roller 58 (Figure 8) the film is always moved its required length throughout the same portion of the cycle, regardless of the diameter of film on either the supply or take-up spools. This, of course, results in much less strain on the various parts of the operating mechanism of the magazine, and also in considerably less load on the camera drive mechanism in case drive 2| (Figure l). Furthermore, through the provision of the gradual acceleration of the film feed drive mechanism at the beginning of the operative cycle, and the gradual deceleration at the end of the cycle, the driving mechanisms are not strained and peak loads are obviated. Furthermore, this gradual acceleration and deceleration of the lm greatly lends to the accuracy of the film metering, as it precludes any possibility of the lms slipping between the film feed roll 58 and the pressure roll 59 (Figure '1).

Film supply spool brake Inasmuch as it is of great importance that a new expanse of iilm be fed into proper exposure position in a very short period of time, substantial momentum is generated in the Film supply spool 30, particularly when it is full of iilrn, and the spool would, if left free to rotate, coast at the end of the winding cycle and permit enough slack to form which might either cause the iilm to be scratched or to become jammed in the magazine, or both. 'We have, accordingly, provided a supply spool braking mechanism which will now be described.

The supply spool braking system is shown in Figures 1, 2, 5, 6 and l2. As shown in Figure 12, the film supply spool spindle 33 is rotatably mounted in bushing 38 and on the spindle is pinned the hub of a drum |04. Encircling drum |04 is a vbrake band |05, one end |05a of which is attached to a stud |06 (Figure 2) mounted on bracket 32, the other end |05b of the brake band being attached to a rigid channel-shaped member |01 similar to channel member 90. This channel slidably extends through and is guided by a pair of spaced pins |08 and |09, secured to and extending from bracket 32, the'other end of channel |01 being attached to a pin |I0 (Figure 5) fastened to an arm III, the lower end of Which rotatably supports one end of roller 51. The upper end of arm I is pivotally secured, as by a screw ||2 to a small bracket 3 which is fastened to the base casting 23. The opposite end of roller 51 (Figure 1) is mounted on a similar arm ||4 pivoted to a similar bracket ||5. These arms and IIA are given a clockwise bias, as Viewed in Figure 5, by a pair of springs and IISa, the opposite ends of which are attached respectively to the arms and the brackets I3 and I l5.

As shown in Figure 2, the lm F is fed from supply spool -30 over and under roller 51 and accordingly the springs ||6 and ||8a tend to take up the slack in the lm as the springs pull roller 51 to the left, as viewed in this gure. As soon as the lm feeding mechanism starts to draw the lm to the right, as viewed in Figure 5, roller 51 is pulled to the right against the bias of springs IIB and |I-6a, and as this happens, brake band is released, thus to free drum |04 so that the lm supply spool 30 (Figure 2) may rotate freely. As the lm F stops moving, roller 51 (Figure 5) is pulled to the left by reason of the bias of springs IIS and Illia, and this movement of the roller being transmitted to arm I, draws brake band |05 tightly around drum |04, thus immediately applying a braking force through the band to the drum and thence to the lm supply spool 30, Thus the braking force applied to the lm supply spool is determined directly by the film itself, and no slack can form subsequent to the feed portion of the operative cycle. When it is necessary for the film supply spool to turn, the braking force on this spool is almost completely removed, the force then immediately being applied to whatever extent is necessary to snub the spool quickly and permit any excessive slack from being created by the nlm spool coasting after the proper amount of hlm has been fed.

Vacuum back At the end of the lm feeding or winding cycle when the unexposed strip of lm has been moved into position for exposure, it is necessary that the uneXposed strip of film be held fiat in the focal plane while the shutter is operated. To this end we have provided What may be termed a vacuum back of the type disclosed in United States Letters Patent No. 1,974,842, issued September 25, 1934, to William A. Black, which, in general, includes mechanism adapted to create a vacuum at the proper predetermined interval in the operative cycle of the camera for holding the nlm ilat over the photographic exposure area during the photograph exposure interval. Our improved vacuum back and the operating mechanism therefor is shown in Figures 2, 5, l1, 14 and 15. As shown in Figure 14, focal plane casting 55 is provided with a series of longitudinal and lateral spaced grooves I|1 which are formed in the casting by first machining the casting flat and then cutting the grooves in this flat face.

, These grooves, illustratively, may be on the order of three-eighths of an inch apart and on the order of twenty-five thousandths of an inch wide and twenty-ve thousandths of an inch deep. As shown in this gure, the grooves terminate short of the edges of the casting, but .are substantially coextensive therewith longitudinally and transversely. As shown in the lefthand portion of Figure 14, the top of casting 55 is provided with a number of channels I I8 which are preferably cast integrally with the casting and lead to a common opening ||9 which is located at the center of one side of casting 55. Channels ||8 are covered by a sheet metal cover plate which is secured to casting 55 by a plurality of screws |2| (see also Figure 15). Disposed between plate |20 and casting 55 is a gasket |22 tfsprevent the leakage of air from the channels At a plurality of points, illustratively eighteen, holes |23 are drilled from the top of casting 55 downwardly (see Figure 11) until they almost break through the bottom machined face of the casting. After these holes |23 are drilled, the bottom face of the casting is machined, as by a circular saw, to provide arcuate slots I 24 (see also Figures 14 and l5) which break into the holes |23 thus placing the longitudinal and transverse slots |I1 into communication with channels il@ by way of the slots |24 and holes I 23. As shown in Figure 14, each of holes |23 communicates with one or more of channels H8, and accordingly the main opening ||9 of the vacuum system is in direct communication with all of the slots |I1. Thus this combination of grooves, holes and channels permits the evacuation of all space between the i'llm and the lower face of casting 55, as viewed in Figure 1l. Channels IIS (Figure 14) are so arranged that the cross-sectional area increases as air comes through the casting 55 at the various holes |23, and the channels are ar ranged in the shortest possible practical paths from these holes to the central opening i0 so that all of the air within this space may be evacuated in the shortest possible time and with the least possible pressure drop. v

As shown in Figure 5, a valve generally indicated at |25 is provided for the vacuum back system and this Valve includes a block |25 and a plunger |21 for controlling the connection to the various channels, holes and grooves in the vacuum back casting 55, Block I 25 (Figure 6) is fastened to bracket 32 by screws |223J and this block includes a passageway |29 which communicates with a, passageway |30 formed in a block I3| secured in any suitable manner to the opposite side of bracket 32. Block I3| includes a second passageway |32, the end of which communicates with the main opening IIS in the vacuum back casting 55 (see Figure 11) and. thus communication may be had between valve |25 and the vacuum back by way of main opening H0 and passa-ges |32, |30 and |29 in the two blocks |3I and |25. A third block |33 (Figure 6) is fastened, as by screws |34 to the outside of casting 23, this third block being provided with passages |35 and |30 and carrying a hose nipple |31 which communicates with passage |36. Passage |35 of block |33 communicates with another passage |38 in block |26 and thus comfmunication may be had between the hose nozzle |31 and valve |25. A rubber hose (not shown) may be placed on nozzle |31 when the camera magazine is installed in the aircraft, for connecting the vacuum mechanism to a motor driven vacuum pump (not shown) or a Venturi tube (not shown). Plunger |21 (Figure 5) has a piston |21a fastened to or formed on the lower end thereof, and when this piston is in the position shown in Figure 5, air can pass freely from Passage |30 (Figure 6) through passage |29 into a chamber |39 (Figure 5) thence out through passages |35 and |36 (Figure 6) in block |33 through nipple |31 and thence to the vacuum pump. Preferably rubber grommets |40 are used to seal the various connections between the drilled passages of the various blocks |26, |3| and |33. Thus it will appear that with the plunger in the Figure position, the space between the back of the film and the bottom of the focal plane casting 56 can quickly be evacuated.

Referring back to Figure 5, gear 69 has a groove |4| formed in the face thereof which receives a roller |42 rotatably mounted on a pin |43 secured to an arm |44, the right-hand end of which is pivoted on a pin |45 mounted in and extending from side casting 34 (Figure 6). The left-hand end of arm |44 (Figure 5) has a slot |46 which receives a pin |41 fastened to the top of plunger |21. It will now appear that as gear 69 rotates during the operative cycle of the magazine, as heretofore described, arm |44 is rocked about the axis of pin |45 as roller |42 follows groove |4| in the gear, and the movement of the arm |44 controls the position of plunger |21 in accordance with the shape of groove |4|. In Figure 5 position, the arm, and accordingly the plunger, are shown in the position in which they would rest when the magazine is in condition for taking pictures, i. e. at the end of the cycle. As soon as gear 69 starts to rotate clockwise, as viewed in Figure 5, at the beginning of the Winding cycle, plunger |21 is moved downward by an amount sufllcient to shut oil.' the vacuum casting 55 from the source of vacuum and open it to the atmosphere by way of a hole |48 drilled through the side of block |26 into chamber |39. Thus air at atmospheric pressure may flow through hole |48 above piston |21a, into chamber |39 and thence through passages |29, |30, |32 and main opening ||9 into the vacuum casting 55 behind the film, thus to release the film so that it may easily be wound. After the film has been wound as heretofore described, and magazine coupling 6| has been rotated about 300, groove |4| has been so rotated as to pivot arm |44 upwardly thus to raise plunger |21 and accordingly piston |21a to the Figure 5 position wherein the piston cuts off the bleeder hole |48 and reconnects the suction with the casting 55 as described. 'I'his 300 rotation leaves the last 60 of motion for flattening the film, the period of time consumed by this remaining amount of the motion being necessary to accomplish the flattening operation by means of a vacuum at very high altitudes.

Light and air locks Large size aerial cameras are capable of taking pictures of substantial dimension, the exposure area being on the order of 9" x 18, and even larger. Where the film i's nine or more inches in width, it is difficult to hold the film flat in the focal plane, as hereinbefore described, without excessive leakage of air into the space between the fllm and the vacuum back and light into the magazine. Unless leakage of air and light is prevented, the film cannot be held flat in the focal plane to prevent distortion, and the illm in the magazine might become fogged. To

the end of preventing this leakage we have provided, as shown in Figures 2, 3, 4 and 5, a pair oi flippers |49 and |50 (Figure 2) disposed at the opposite ends of base casting 23 in transverse channels |5| and |52. By placing the flippers in channels |5| and |52, light entering the camera through the camera lens cannot readily pass around the flippers and then up into the magazine chamber where it could fog the entire roll of film. Thus the flippers extend entirely across the ends of the magazine and at the end of the operative cycle are in the slant position shown in Figure 2. With the flippers in this position, their elevated upper edges are pressed against the film, thus forcing the film upwardly against the bottom of the focal plane casting 55 (Figure 5) all the lway across each end thereof. The grooves 23h (Figure 10) in base casting 23 guide the edges of the film and hold it close enough to the bottom of the focal plane casting 55 so that the air leakage around these edges is not excessive.

As flippers |49 and |50 are the same, only one of them, namely flipper |49, will be described. Ag shown in Figure 3, the opposite ends of flipper |49 are provided with pivot pins, such as pin |49a, which pins extend into the opposite side walls of base casting 23 so as to pivotally mount the flipper within its recess |5|. Fastened to one end of the flipper is an angle arm |53 (Figure 2) to the upper end of which is attached a spring |54. the other end of the spring being fastened to a lever |55 pivotedag at |56 to bracket ||3. This spring constantly biases flipper |40 counterclockwise (as viewed in Figure 2), i. e. into the slanted position shown wherein the elevated upper edge of the flipper presses the nlm against the focal plane casting. Flipper |50 (Figure 3) is similarly pivoted by pins, such as pin |51, and also has an angle arm |58 to which is attached a spring |59 (Figure 2) biasing this flipper clockwise into its slanted position.

During the winding portion of the magazines operative cycle, it is necessary to rock flippers |49 and |50 from their slanted position to lower their elevated upper edges from the film. This movement of the flippers is accomplished by a rotatable cam |60 (Figure 3) which is fastened to and accordingly rotated by coupling shaft 62 (Figure 1l) so as to make one complete rotation during each cycle of operation. Referring back to Figure 3, cam |60 rotates counterclockwise and accordingly starting from the position shown, forces the end |5| of a bell crank lever |62 outwardly or clockwise about its pivot |63 until the end |6| of the lever rides on the dwell |60a of the cam. Pivot |53 comprises a pin carried in a lever |64, which lever is pivoted on a stud |55 fastened to and extending upwardly from base casting 23. Lever |64, however, remains stationary during this initial clockwise rocking of bell crank |62. As the bell crank lever rocks, its slotted end |56 moves to the right. and as this end of the lever is fastened to a rod |61 by a pin |68 which extends through the slot in bell crank arm |66, the rod |51 is also moved to the right. The right-hand end of rod |51 is fastened to the upper end of a lever |69 pivotally mounted on a stud |10 fastened to the base casting 23 so that when the rod moves to the right, this lever |69 is rocked clockwise. The lower end of leve;` |69 is connected to arm |58 of flipper |50 by a rod |1| `so that when lever |69 is rocked clockwise, as described, rod |1| is moved to the left, thus to rock flipper |50 counterclockwise, as viewed in Figure 2, to lower its elevated upper edge out of engagement with the nlm.

The left-hand end of rod |61 is pivotally iastened to a lever |12 piveted on a stud |19 fastened to the base casting 23. The lower end of lever |12 is fastened as by a rod |14 to arm |53 of flipper |49. Thus it will follow that as rod |61 is moved to the right during the initial rotation of cam |60, as described, lever |12 is rocked counterclockwise, thus pulling flipper arm |53 clockwise, as viewed in Figure 2, to lower the elevated upper edge of flipper |49 out of engagement with the film. Hence with both of the flippers lowered, as described, the lm may be fed freely through the magazine as heretofore described. By reason of the substantial extent of dwell IGM (Figure 3) on cam |69, the flippers are held in their lowered position during a sufflicient portion of the operative cycle so as not to interfere with the feeding of the film through the magazine. After the proper amount of film has been metered through the magazine, cam |69 has rotated to the point where arm ISI (Figure 3) of bell crank |62 drops off cam dwell |690.. When this occurs, the lever system heretofore described operates in the oppo-site direction under the bias of springs |54 and |59 (Figure 2) to rock flippers |49 and |50, respectively, into their slanted position shown, wherein the film is again pressed tightly in proper position to prevent escape or leakage of air into the space between the lm and the focal plane casting.

As shown in Figure 2, each of rods |1| and |14, as for example rod |14, is secured to its flipper arm by a nut and lock nut arrangement |15 to permit the adjustment of flippers |49 and |50 so that each will operate correctly while obviating the necessity of machining and assembling these parts to exceedingly close tolerances.

Safety light lock The camera magazine 22 (Figure 1) may be detachably secured to the body 2| of the camera in any suitable manner, but preferably thisv is accomplished by means of a pair of oppositely disposed locking bars, such as bar |16 shown in Figure 1G, which may be moved by suitable means (not shown) between the solid and dotted line positions; the solid line position being the magazine attaching position, and the dotted line position being that in which the magazine may be removed. Since magazine 22 as so far describe-d is not provided with the conventional light slide, one exposure is allowed to become light struck at the time the magazine is removed from the camera. Ordinarily the magazine is at the end of its operative cycle when removed, which means that iiippers |49 and |59 (Figure 2) are rocked to the slanted position shown. In this position, as pointed out before, the flippers prevent any light from getting past the ends of the exposed film area and around into the interior of the magazine where it would fog the film. It might occur, however, that the operator would stop with the camera partially wound and then remove the magazine, under which circumstances the ippers would not he in their slanted position so that light could enter the magazine past the flippers and fog the remaining lm in the magazine. We have further pro-vided a, safety mechanism to cause the flippers to raise to the Figure 2 position, thus closing off any openings through which light might leak when the magazine is removed from the camera.

Locking bar |16 (Figure 10) when in its solid line position overlies a ledge |11 on base casting 23, and when the locking bar is in this position it presses against a pin |18 (Figure 3) to hold in the pin. When the locking bar is moved off the ledge, pin |18 is free and the pressure exerted by springs |54 and |59 (Figure 2) on the operating mechanism or flippers |49 and |50 pulls to the left on rod |14 and to the right on rod l1 I, pushing rod |61 (Figure 8) to the left, and accordingly ond |66 of bell crank |62 also to the left. Since the end of the bell crank arm IG! is held by cam |59 .from moving inwardly, pivot pin |63 is forced outwardly, i. e. away from rod |51. As noted before, lever |54 is pivoted to stud |65 so that lever |54 is rocked clockwise upon the above-described movementof pin |63. Lever |54 is attached to one end of a toggle |19, the center pivot |19a of which is fastened to pin |18. The other end of toggle 19 is fastened to a xed pivot |80. Thus, when lever |64 is rocked clockwise, as described, the toggle is pulled, thus forcing pin |19 outwardly to permit springs |54 and |59 (Figure 2) to rock flippers |49 and |5l| to the slant position shown, and thereby close up the gaps at the end of the eX- posure area.

Magazine cover interloclcs When the magazine is taken to the dark room for loading lm, it is convenient to have the ippers in the horizontal position so that the film may easily be threaded through the magazine. To this end flipper arm |53 (Figure 2) includes a bent-up lip IBI. Lever |55 includes a foot |82, the end of which is positioned close to lip i8 As shown in Figure 4, flipper arm |58 is also provided with a lip |83, which is disposed adjacent the foot iil of a lever which is similar to lever |55 (Figure 2). Foot |94 (Figure 4) of lever |65 is provided with a pin |89 to which is attached one end of a spring |81, the other end of which is attached to a fixed pin |88, the spring thus constantly biasing lever clockwise, as viewed in Figure 4. A similar spring (not shown) is attached to the foot of lever |55 (Figure 2) and accordingly places this lever under a counterclockwise bias, as viewed in this figure. Accordingly, both of levers |55 and |85 if free to do so, may rock in the directions indicated so that their respective feet |82 (Figure 2) and |94 (Figure 4) press flipper arm lips l! (Figure 2) and |83 (Figure 4.) in such a manner as to rock the flippers out of their slanted positions, as viewed in Figure 2, so that the ilm may readily be threaded through the magazine.

AS shown in Figure 2, levers |55 and |85 are respectively provided with outwardly extending arms |89 and |90, and these arms and accordingly the respective levers, are held in the position shown when cover 2'6 is on the magazine. However, when the magazine cover is removed in the dark room for unloading and reloading the magazine, lever arms |89 and |99 are free to move outwardly as the levers pivot under the bias of the springs attached thereto, as described above, t0 rock the flippers into horizontal position out of the way of the film.

The removal of cover 29 from the camera magazine performs another function.. When arm |90 (Figure 4) for example, is in the position shown, and cover 29 is in place, a spring |9|, which has one end attached to a pin |92 on a projection |93 of arm |90 pulls on another pin |94 to which the other end of the spring |9| is attached. This latter pin is fastened to an arm |95 which is `pivoted on a stud |96. Arm

|95 carries a stud |91 on which one end of pressure roller 59 is rotatably mounted. The other end of roller 59 (Figure '7) is similarly supported so that a spring |99, similar in deposition and function to spring |9i, coacts with spring |9| to provide the tension which holds the pressure roller 59 against the lm and against roller 59 so that the pressure roller bears with equal pressure throughout its length. When cover 29 is removed and arm |90 moves clockwise, as viewed in Figure 4, and as described above, a pin |99 mounted on the projection |93 of arm |90 moves to the right and engages the left-hand side of arm |95 to lift pressure roller 59 away from the film and from the feed roller 58. Thus when the cover 29 is removed from the magazine, the film may be threa'tled easily through the magazine and around and over feed roller 58 and under pressure roller 59. Preferably we provide a guide plate 200 which extends across base casting 23 in the corner thereof to guide the end of the film underneath roller 59 when cover 29 is off and the roller is out of its pressure position. Thus it will appear that removal of the magazine cover 29 automatically conditions the magazine for the ready passage therethrough of the leading edge of a new strip of lm to facilitate reloading the magazine.

Film feed indicator We have found it desirable to indicate whether or not the film is moving properly through the magazine during the winding portion of the cycle. To this end we have provided a small telltale 2'0I (Figure 2) which is disposed in a recess 202 (Figure 12) in the outside of the base casting 23. This telltale is carried on a shaft 203 rotatably mounted in a bushing 204 fastened to the side wall of base casting 23. The other end of shaft 204 supports a pulley 205 on which The telltale is, of course, useful only when,

the camera is mouted in an accessible position wherein it is readily visible to the operator.

Remote film feed indicator As noted above, the camera is frequently mounted in an inaccessible position in the airpiane` and accordingly we have provided a remote indicator to indicate whether or not the film is moving through the magazine in proper fashion. This remote indicator includes an electric switch, generally indicated at 208 (Figures 5 and 12) having an actuating button 209 adapted to be depressed by a leaf spring 2|0 which is cyclically depressed by the high portion of an eccentric cam 2| which is fastened to pulley 205 and accordingly rotates therewith when the pulley is driven by belt 206. This switch 208 may be used to control a blinker light not shown) at a remote station, and may also be used to control a remote solenoid operated counter (not shown) to record the number of exposures taken by the magazine.

When switch 208 is used to operate or control a remote solenoid operated counter, it is neces* sary that the switch close once during each cycle and then open again, i. e. the switch must oper ate once and only once for each magazine cycle. In this connection a stud 2|2 (Figure 5A) is fastened to casting 34 and extends inwardly thereof, and rockably mounted on this stud are a pair of arms 2'|3 and 2M. Arm 2|3 (Figure 5) includes a downwardly extending tail 2|5 which lies in the path of a pin 2|5 fastened to gear 69, which pin engages tail 2|5 once for every revolution of the gear to rock arm 2|3 about stud 2|2. The free end of arm 2|3 has fastened thereto one end of a spring, the lower end of which is attached to arm 2|8 of a counter 2|9 so that for every revolution of gear 69, counter 2|9 is actuated once, thus to show how many exposures have been taken.

.As noted above, switch 208, when used to operate a remote solenoid operated counter, must operate once and only once for each magazine cycle. To this end, the diameters or" pulleys 205 and 201 (Figure l2) are so selected that when the film supply spool is full, in which case it will have the smallest rotation for the full travel of the film, the telltale pulley 205 would ordinarily be driven more than one revolution. Accordingly a hub 220 (Figure 5A) is mounted on stud 2|2 and is fastened to both of arms 2|3 and 2 I4. The extreme end of arm 2id (Figure 5) is provided with a projection 22| adapted to engage a notch 222 in the surface of cam 2| Arm 2|4 is in the position shown in Figure 5 at the end of the operative cycle or at the beginning thereof so that as the lm supply spool begins to revolve the telltale 20| (Figure l2) is restrained by the projection 22|, the spring belt 205 slipping on one or the other of pulleys 205 and 201. As arm 2 I3 (Figure 5) is rotated clockwise, as described above, however, arm 2M beingconnected to arm 2|3 by hub 220 (Figure 5A) is lifted and the projection or tip 22| (Figure 5) is removed from notch 222 in cam 2il. The arm tip is held clear of the cam permitting telltale 20| (Figure 12) to rotate for several degrees, as long as pin 2|6 (Figure 5) engages tail 2|5 of arm 2|3, and when the pin 2|6 passes tail arm 2|5, arm 2|3 is released and accordingly tip 22| of arm 2M drops back onto the surface of cam 2|| but not into notch 222, as the notch is not in position to receive the arm tip at this time. A spring 223 has its upper end fastened to arm 2M and its lower end fastened to base casting 23, and accordingly constantly biases arm 2 M counterclockwise to hold its tip 22| in engagement with cam 2| l. Cain 2| however, is rotated by spring belt 206 through one complete revolution, accordingly operating switch 208 a single time, as described above, and at the end of the cams revolution, arm tip 2 II drops into notch 2.22 to stop cam 2|| against further rotation. From this point on to the end of the winding cycle, the spring belt 206 merely slips on one pulley or the other and accordingly the remotely controlled counter solenoid is operated but once per operative cycle of the magazine.

It will now appear that we have provided a camera magazine which attains the several objects set forth hereinabove in a thoroughly practical and efficient manner.

As many possible embodiments may be made of the above invention and as many changes might be made in the embodiment above set forth, it is to be understood that all matter hereinbeforeA set forth or shown in the accompanying drawings is to be interpreted as illustrative and not ina limiting sense;

We. claimt l. In camera construction, in combination, a cone member having a ledge formed n the top thereof, a film magazine member including a bottom casting adapted to be supported on said ledge, means on one of said members for detachably connecting both of said members, means in said magazine forming a focal plane in which a film is adapted to be positioned for exposure, -means forming light locks at opposite ends of said focal plane and movable into engagement with said focal plane means to preclude entrance of light thereby into said magazine, and means on said magazine engageable with said firstmentioned means upon movement thereof to detach said members for effecting movement of said light lock means into engagement with said focal plane means;

2. In camera construction, in combination, a cone, a film magazine, means in said magazine forming a focal plane in which a lm is adapted to be positioned for exposure, means forming light locks at opposite ends of said focal plane and normally in engagement therewith when the film magazine is detached from the cone to preclude entrance of light into said magazine, means for detachably securing said magazine on said cone, and means associated with said magazine and operable by said securing means when the magazine is secured to the cone for moving said light lock means out of engagement with said focal plane.

3. In camera construction, in combination, a cone, a film magazine, means in said magazine forming a focal plane in which a film is adapted to be positioned for exposure, means forming light locks at opposite ends of said focal plane and normally in engagement therewith when the lm magazine is detached from the cone to preclude entrance of light into said magazine, means for detachably securing said magazine on said cone, means associated with said magazine and operable by said securing means when the magazine is secured to the cone for moving said light lock means out of engagement with said focal plane, and spring means associated with said light lock means for biasing said light lock means into light locking position.

4. In camera construction, in combination, a film supply spool, a film take-up spool, means defining an exposure area for lm fed from one spool to the other, film feeding means for feeding film into said area, a stationary plate deiining the focal plane of said camera coextensive with said area, means at the entrance and exit ends of said area for clamping the film against said plate after film has been fed into said area, said clamping means comprising elongated bars pivotally mounted at opposite ends of said plate and movable toward and away therefrom whereby upon movement of said bars toward said plate the film is clamped thereaganst, and means forming an operative connection between said clamping bars and said film feeding means and effective only during the latter portion of the operative cycle of said film feeding means for effecting clamping operation of said clamping means.

5. In camera construction, in combination, a base, a film magazine, lm supply and take-up spools rotatably mounted in said magazine, a detachable cover for said magazine, means detachably mounting said film magazine on said base, means in said magazine formingY a focal plane in which a film is adapted to be positioned for exposure, means forming light locks at opposite ends of saidfocal plane forming means and movable into locking position to preclude entrance of light into said magazine, means responsive to detaching operation of said iirstmentioned means for effecting movement of said locking means into their locking position, and means responsive to removal of said cover from the magazine for effecting movement of said locking means out of their locking position.

6L In a camera construction, in combination, a cone, a magazine detachably mounted on said cone, supporting structure in said magazine, filmy supply and take-up spools rotatably mounted on said structure, a frame-like base underlying said structure, said base including means forming guides on opposite sides thereof for guiding the edges of the film during its passage from one spool to another, a stationary vacuum back resting on said base beneath said spools and adjacent said guide means, said vacuum back defining the focal plane of the camera, and means disposed at the entrance and exit ends of the focal plane and extending transversely of a strip of film and responsive to detachment of the magazine from said cone for engaging the film lying under the vacuum back and pressing it upwardly against the vacuum back to preclude entrance of light between the lm and Vacuum back.

7. In a camera magazine adapted to be detachably mounted on a cone, the combination of, supporting structure, film supply and take-up spools rotatably mounted on said structure, a frame-like base underlying said structure, said base including means forming guides on opposite sides thereof for guiding the edges of the film during its passage from one spool to another, a stationary vacuum back resting on said base beneath said spools and adjacent said guide means, said vacuum back defining the focal plane of the camera, means disposed at the entrance and exit ends of the focal plane and extending transversely of a stripI of film for engaging the film lying under the vacuum back and pressing it upwardly against the vacuum back to preclude entrance of air between the film and vacuum back when the vacuum back is operated to draw the film fiat thereagainst, and means responsive to removal of the magazine from said cone for effecting film engaging operation of said film engaging means, thereby to preclude entrance of light into said magazine.

8. In a camera magazine adapted to be detachably mounted on a cone, the combination of, supporting structure, film supply and take-up spools rotatably mounted on said structure, a frame-like base underlying said structure, said base having a passageway formed therein along which the film may move from one spool to the other, a stationary vacuum back resting on said base and forming a top to said passageway, and means disposed at the entrance and exit ends of said passageway and extending transversely of said vacuum back and movable into and out of blocking position relative to the entrance and exit ends of said passageway, thereby to preclude the entrance of light into the magazine when moved into blocking position.

9. In a camera magazine adapted to be detachably mounted on a cone, the combination of, supporting structur, lm supply and take-up spools rotatably mounted on said structure, a

Vframe-like base underlying said structure, said base having a passageway formed therein along which the film may move from one spool to the other, a stationary vacuum back resting on said base and forming a top to said passageway, means disposed at the entrance and exit ends of said passageway and extending transversely of said vacuum back and movable into and out of blocking position relative to the entrance and exit ends of said passageway, thereby to preclude the entrance of light into the magazine when moved into blocking position, and means responsive to the removal of the magazine from said cone for effecting movement of said blocking means into blocking position to preclude entrance of light into said magazine when it is removed from said cone.

10. In a camera magazine adapted to b'e detachably mounted on a cone, the combination of, supporting structure, lm supply and take-up spools rotatably mounted on said structure, a frame-like base underlying said structure, said base having a passageway formed therein along which the film may move from one spool to the other, a stationary vacuum back resting on said 'base and forming a top to said passageway, means disposed at the entrance and exit ends of said passageway and extending transversely of said vacuum back and movable into and out of blocking position relative to the entrance and exit ends of said passageway, thereby to preclude the entrance of light into the magazine when moved into blocking position, means responsive to the removal of the magazine from said cone for effecting movement of said blocking means into blocking position to preclude entrance of light into said magazine when it is removed from said cone, a cover detachably mounted on said magazine, and means responsive to removal of said cover from said magazine for moving said light blocking means out of light blocking position.

IRVING W. DOYLE. REGINALD A. WHITE. 

